Targetable mechanisms driving immunoevasion of persistent senescent cells link chemotherapy-resistant cancer to aging
Denise P. Muñoz, Steven M. Yannone, Anneleen Daemen, Yu Sun, Funda Vakar-Lopez, Misako Kawahara, Adam M. Freund, Francis Rodier, Jennifer D. Wu, Pierre-Yves Desprez, David H. Raulet, Peter S. Nelson, Laura J. van ’t Veer, Judith Campisi, Jean-Philippe Coppé
Denise P. Muñoz, Steven M. Yannone, Anneleen Daemen, Yu Sun, Funda Vakar-Lopez, Misako Kawahara, Adam M. Freund, Francis Rodier, Jennifer D. Wu, Pierre-Yves Desprez, David H. Raulet, Peter S. Nelson, Laura J. van ’t Veer, Judith Campisi, Jean-Philippe Coppé
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Research Article Aging Oncology

Targetable mechanisms driving immunoevasion of persistent senescent cells link chemotherapy-resistant cancer to aging

Abstract

Cellular senescence is a tumor-suppressive mechanism that can paradoxically contribute to aging pathologies. Despite evidence of immune clearance in mouse models, it is not known how senescent cells (SnCs) persist and accumulate with age or in tumors in individuals. Here, we identify cooperative mechanisms that orchestrate the immunoevasion and persistence of normal and cancer human SnCs through extracellular targeting of natural killer receptor signaling. Damaged SnCs avoided immune recognition through MMP-dependent shedding of NKG2D ligands reinforced via paracrine suppression of NKG2D receptor–mediated immunosurveillance. These coordinated immunoediting processes were evident in residual, drug-resistant tumors from cohorts of more than 700 prostate and breast cancer patients treated with senescence-inducing genotoxic chemotherapies. Unlike in mice, these reversible senescence subversion mechanisms were independent of p53/p16 and exacerbated in oncogenic RAS-induced senescence. Critically, the p16INK4A tumor suppressor could disengage the senescence growth arrest from the damage-associated immune senescence program, which was manifest in benign nevus lesions, where indolent SnCs accumulated over time and preserved a non-proinflammatory tissue microenvironment maintaining NKG2D-mediated immunosurveillance. Our study shows how subpopulations of SnCs elude immunosurveillance and reveals potential secretome-targeted therapeutic strategies to selectively eliminate — and restore the clearance of — the detrimental SnCs that actively persist after chemotherapy and accumulate at sites of aging pathologies.

Authors

Denise P. Muñoz, Steven M. Yannone, Anneleen Daemen, Yu Sun, Funda Vakar-Lopez, Misako Kawahara, Adam M. Freund, Francis Rodier, Jennifer D. Wu, Pierre-Yves Desprez, David H. Raulet, Peter S. Nelson, Laura J. van ’t Veer, Judith Campisi, Jean-Philippe Coppé

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Figure 9

Coordinated upregulation of MMPs and downregulation of NKG2D occurs in prostate tumors where NKG2D-L–expressing SnCs persist after genotoxic chemotherapy, but not in adjacent noncancerous normal tissues.

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Coordinated upregulation of MMPs and downregulation of NKG2D occurs in p...
(A) Pairwise comparison of MMP expression before and after genotoxic chemotherapy in patients with prostate cancer. Analyses and displays are explained in the Figure 1A legend. An additional set of 20 laser-captured tumor areas isolated from 10 patients before versus after neoadjuvant mitoxantrone therapy is included for validation (purple markers/lines). (B) MMP3 detection by IHC in prostate cancer tissues from patients treated or not with mitoxantrone/docetaxel (MIT/DTX; original magnification, ×4). Tumors from 26 patients not subjected to therapy were compared with tumors from 50 patients receiving MIT/DTX. Histopathology and staining assessment are color coded as 0 (no staining), +1 (detectable), +2 (intermediate), +3 (high). Distribution of each staining intensity level is shown as pie charts below a representative image of intense staining in either condition. (C) Pairwise comparison of NKG2D expression before and after chemotherapy, as described in A. (D) Comparison of MMP, NKG2D ligand, and NKG2D expression profiles in tumor versus normal prostate tissue (top vs. bottom panels) before and after chemotherapy. The 2 sets of 20 paired tissues collected from 10 patients were pooled and plotted by gene type: MMPs (MMP-1, -3, -10, -12; left), NKG2D ligands (MICA, -B, ULBP-1, -2, -3; middle), NKG2D receptor (right). Results are displayed as values before (x axis) compared with after (y axis) chemotherapy. Overall fold change (FC; averaged across patients) and significance (P value, Student’s t test, paired, 2 tails) across MMPs, NKG2D ligands, and NKG2D are shown.